Methylation is one of the major epigenetic processes pivotal to our understanding of carcinogenesis. It is now widely accepted that there is a relationship between DNA methylation, chromatin structure, and human malignancies. DNA methylation is potentially an important clinical marker in cancer molecular diagnostics. Understanding epigenetic modifications in their biological context involves several aspects of DNA methylation analysis. These aspects include the de novo discovery of differentially methylated genes, the analysis of methylation patterns, and the determination of differences in the degree of methylation. Here we present a previously uncharacterized method for high-throughput DNA methylation analysis that utilizes MALDI-TOF mass spectrometry (MS) analysis of base-specifically cleaved amplification products. We use the IGF2͞H19 region to show that a single base-specific cleavage reaction is sufficient to discover methylation sites and to determine methylation ratios within a selected target region. A combination of cleavage reactions enables the complete evaluation of all relevant aspects of DNA methylation, with most CpGs represented in multiple reactions. We successfully applied this technology under high-throughput conditions to quantitatively assess methylation differences between normal and neoplastic lung cancer tissue samples from 48 patients in 47 genes and demonstrate that the quantitative methylation results allow accurate classification of samples according to their histopathology. lung cancer ͉ MALDI-TOF MS ͉ epigenetics
For 30 years, the prevailing view has been that the hydrophobic effect contributes considerably more than hydrogen bonding to the conformational stability of globular proteins. The results and reasoning presented here suggest that hydrogen bonding and the hydrophobic effect make comparable contributions to the conformational stability of ribonuclease T1 (RNase T1). When RNase T1 folds, 86 intramolecular hydrogen bonds with an average length of 2.95 A are formed. Twelve mutants of RNase T1 [Tyr----Phe (5), Ser----Ala (3), and Asn----Ala (4)] have been prepared that remove 17 of the hydrogen bonds with an average length of 2.93 A. On the basis of urea and thermal unfolding studies of these mutants, the average decrease in conformational stability due to hydrogen bonding is 1.3 kcal/mol per hydrogen bond. This estimate is in good agreement with results from several related systems. Thus, we estimate that hydrogen bonding contributes about 110 kcal/mol to the conformational stability of RNase T1 and that this is comparable to the contribution of the hydrophobic effect. Accepting the idea that intramolecular hydrogen bonds contribute 1.3 +/- 0.6 kcal/mol to the stability of systems in an aqueous environment makes it easier to understand the stability of the "molten globule" states of proteins, and the alpha-helical conformations of small peptides.
An efficient method for the construction of multiple mutations in a sequential manner is described. It is based on the gapped duplex DNA approach to oligonucleotide-directed mutagenesis (Kramer et al. 1984, Nucl. Acids Res. 12, 9441-9456) and a set of newly constructed phasmid vectors. These are characterized by the following features. Presence of the phage fl replication origin permits ready conversion to the single stranded DNA form. An amber mutation within, alternatively, the bla or cat gene provides a means for ready selection of the strand into which the mutagenic oligonucleotide has been incorporated. By means of the alternating antibiotic resistance markers any number of mutations can be constructed in consecutive rounds of mutagenesis. The optional presence of gene expression signals allows the direct overproduction of structurally altered proteins without re-cloning. Both the mutagenesis and expression aspects were tested using the lacZ gene as a model.
Neutralizing the interaction of the platelet receptor gpIb with VWF is an attractive strategy to treat and prevent thrombotic complications. ALX-0081 is a bivalent Nanobody which specifically targets the gpIb-binding site of VWF and interacts avidly with VWF. Nanobodies are therapeutic proteins derived from naturally occurring heavy-chain-only Abs and combine a small molecular size with a high inherent stability. ALX-0081 exerts potent IntroductionThe successive adhesion, activation, and aggregation of platelets are key processes in arterial thrombus formation after endothelial damage. 1,2 Both rupture of atherosclerotic plaques as well as surgical interventions to treat atherosclerosis (eg, percutaneous coronary intervention [PCI]) may cause exposure of the subendothelium and subsequent clot formation. Eventually, this can result in the occlusion of arteries, leading to ischemia, myocardial infarcts, or stroke. Given the central role of platelets in thrombosis, a substantial number of currently marketed antithrombotic drugs, such as aspirin, clopidogrel, and abciximab, target different steps involved in platelet activation and aggregation. 1,2 Thanks to their complementary mechanisms of action, the combination of these agents inhibits platelet aggregation to a greater extent than either agent alone. 3 However, the use of these antiplatelet drugs is hampered by an increased bleeding risk 1,2 and the occurrence of treatment resistance in some patients. 4 Moreover, the irreversible nature of their action can complicate the staunching of bleeding. 1,2 Inhibition of the initial adhesion of platelets to subendothelial collagen provides an alternative strategy to prevent unwanted clot formation. The plasma glycoprotein VWF plays a pivotal role in this adhesion via binding to exposed collagen on the one hand, and the interaction of its A1 domain with the gpIb-IX-V receptor complex on the surface of platelets on the other hand. [5][6][7] Interestingly, the VWF A1 domain is only exposed under high-shear conditions, 8,9 so VWF only acts as a bridging molecule between collagen and platelets in small or stenosed arteries. Therefore, it is expected that drugs inhibiting this interaction between VWF and platelets show an improved safety profile with respect to bleeding tendency. Indeed, the antithrombotic effect of several compounds targeting the gpIb-VWF-A1-axis, like aurintricarboxylic acid, 10-12 recombinant VWF fragments, 10,13-16 a recombinant gpIb chimeric protein, 17,18 anti-VWF mAbs, [19][20][21][22][23][24][25][26][27] and an anti-VWF aptamer 28 has been demonstrated in vitro and in vivo, without increasing the bleeding risk. 13,[16][17][18]21,23,25,28,29 Nevertheless, until now only 3 drug candidates have been evaluated in humans, including ALX-0081. [30][31][32][33] We developed ALX-0081, a bivalent humanized Nanobody directed against the A1 domain of VWF. Nanobodies are therapeutic proteins derived from the heavy-chain variable domains (VHH) that occur naturally in heavy-chain-only Igs of Camelidae. 34,35 Here we...
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